DE102018105643B3 - Method for uninterruptible power supply by means of a rapid-fire system and rapid-fire system - Google Patents

Abstract

The rapid standby system (SBA) for the uninterruptible supply of electricity, heat and fuel in the event of a fault or blackout has new technical possibilities that go beyond the state of the art. The possibilities beyond the state of the art relate in particular to the ability of the Deionat- and CO-separation as well as the CO-liquefaction by CO heat pump with the aim of a long-term storage of deionized and CO (liquid) .The high efficiency of the rapid standby system is that it can take excess electricity from the upstream supply network to make it a storable chemical energy source With the energy carrier methanol, which is catalytically produced by means of electrolysis hydrogen and exhaust COin of a methanol synthesis, the rapid standby system can work independently of the mains and at the same time take care of the production process rge to return to storage after a network recovery.

Description

The invention is to be classified in the field of energy supply and serves to produce an uninterruptible power supply in the event of a power failure.

Quick standby systems are used to prevent power outages within sensitive consumer groups. These include in particular residential areas, industrial parks, schools, hospitals, food markets, cold stores, sports stadiums, aviation and shipping ports, water supply facilities, wind and solar parks and retirement homes. These consumers usually have an emergency generator that is powered by a diesel engine.

Current fast-response systems in the form of power generation or emergency generators have only the task of emergency operation and thus to ensure a temporary independence of power grids. Such units are operated on the basis of internal combustion engines (usually gasoline or diesel fuel). The power supply is made possible by a cold start, resulting in longer reaction times. In addition, conventional systems are not designed for a longer term.

A quick-response system for emergency power supply of signaling systems is described in DE L0014435M AZ. The quick-response system is powered by a battery, which serves as a source of energy for a DC motor. The DC motor is connected via a shaft with an alternator. On the shaft between the DC motor and alternator is a flywheel.

For emergency power supply of a lighting system of airfields is in DE 197 70 75 U discloses a quick-response system, which has a diesel generator with connected alternator. Between diesel engine and alternator, a flywheel is used.

DE 14 65 803 A discloses a quick standby system for emergency power supply to consumers and consists of a three-phase motor, a flywheel and an alternator, which takes over the supply of consumers. In the event of a power failure, the generator is powered by the flywheel until a diesel engine drives the generator shaft.

In the publication DE 20 2009 019 105 U1 discloses a system for providing an energy source using carbon dioxide as a carbon source and electrical energy. As an energy carrier methanol is called. A Silicon-Fire CO ₂ capture provides CO ₂ from flue gas to a methanol synthesis plant. The methanol synthesis is preferably fed hydrogen from an electrolysis plant. The Silicon-Fire system is also used to provide control energy. For this purpose, the system is adjusted as needed in its operating point.

In DE 10 2005 046 746 A1 A method for providing energy is described wherein a process storage liquid (eg, methanol) is used as the energy transport and storage medium. Finally, the desired end product in the fuel cell represents the electrical energy. The focus here is on energy generation and storage, which are not designed for use in a fast-response system. The methanol synthesis is also used in other applications as in WO 1997/003 937 A1 or in the DE 10 2009 007 567 A1 described and have the power generation as an object.

Quick-release systems according to the above-mentioned prior art are characterized in that they can exclusively safeguard an emergency operation which involves emergency lighting and / or emergency driving of technical installations, e.g. Pumping operation, a pump system provides. Prior art rapid standby systems are unable to deliver power, heat and fuel and recover heat, deionized and carbon dioxide.

The publication DE 101 18 353 A1 discloses a device for uninterruptible power supply. It has a fuel cell for power generation by cold oxidation of hydrogen to water in case of failure of a main power source, especially in case of failure of a power grid, and a memory for the hydrogen. For the hydrogen storage in methanol, the use of CO2 from the air, here outside or ambient air, called.

WO 2012/028 326 A1 describes a method for the carbon dioxide-neutral compensation of fluctuations in the flow of electricity in a power grid, in particular with regenerative energy sources. In a generation peak of electrical energy from a preferably regenerative energy source is used in an electrolysis unit for hydrogen production in particular of water. The hydrogen is fed to a reactor unit for the catalytic production of methanol or methane. The generated hydrocarbon-containing energy carrier is burned at least partially and as needed in a combustion chamber and the thermal energy of the combustion formed Flue gas flow is used to generate electrical energy in a gas turbine process and / or in a steam turbine process, and the generated electrical energy is fed into the power grid. The flue gas is at least partially supplied as a carbon source for the production of the hydrocarbonaceous energy carrier of the reactor unit.

In WO 2000 025 380 A2 For example, a method for storing electrical energy or hydrogen is disclosed. The process comprises the steps of (a) electrolysis of water to obtain hydrogen; (b) reacting the hydrogen from step (a) with carbon dioxide to form at least one storage medium, preferably methanol; (c) storing the memory connection; and (d) subsequently converting the storage compound back into hydrogen or using the storage connection to operate an internal combustion engine or generate electricity directly or indirectly.

In US 2006/0 078 773 A1 discloses a system for providing emergency power to a load powered by a primary power source. A reserve power is to be provided by an ultracapacitor and / or a battery and / or a fuel cell. A controller controls the application of the reserve power to the load when a deterioration of the power of the primary power source is detected.

DE 197 22 598 A1 describes a fuel cell system. In the operating state of the fuel cell system, an anode, in particular a water / methanol mixture, and the cathode compartment an oxidant, in particular oxygen, can be supplied to the anode compartment. The fuel cell system can be used as a combination of an uninterruptible power supply and an emergency generator.

Out US Pat. No. 6,555,989 B1 is a power generation system that includes a fuel cell and a rechargeable storage battery that are coupled together via a DC-DC converter. While the battery unit serves to maintain voltage and helps to stabilize the fuel cell process, the fuel cell uses methane or methanol, which are converted into the actual usable energy source, here hydrogen, chemically.

US 2010/0 266 917 A1 pursues the goal, by means of an artificial load or a voltage increase at the feed point of a fuel cell system, used here as an uninterruptible power supply to keep the fuel cell system in operation and to protect the membranes of the fuel cell from drying out. After operation for a time sufficient to rehydrate the fuel cell stack, the operation of the fuel cell system may be stopped. As input products of the fuel cell system, hydrogen and atmospheric oxygen are called. The feedstocks are provided from a supply system.

DE 103 07 112 A1 discloses a system for storage and recovery of renewable energy. Hydrogen production uses electrolysis. The reconversion of the hydrogen takes place via a fuel cell. The oxygen for the fuel cell reaction is sourced from the atmosphere. The hydrogen produced by the electrolysis is to be stored in a pressure tank, which is fluidically connected to the device for generating hydrogen.

DE 10 2015 118 736 A1 relates to a method and apparatus for power and air conditioning for stationary and mobile applications and a stationary or mobile application thereto. Renewable energy is stored in the form of methanol and fed to an emergency power system. For this purpose, room air is dehumidified, the CO2 oxygen is added from an electrolysis of the air, the air is humidified and heated to nominal temperature. The resulting process heat is used to drive an absorption heat pump. The by-products CO2 and hydrogen are catalytically bound to methanol and stored in a tank. In the event of a power failure or power failure, the methanol in a direct methanol fuel cell is converted back into electricity and heat.

Presentation of the invention

The object of the invention is to provide a rapid standby plant for avoiding power outages (blackout), which provides excess electrical energy from regenerative plants as chemically stored energy in a storage medium, preferably methanol, for emergencies. It is of particular interest to be able to operate an alternative supply source in the event of a power failure in the shortest possible time.

The object is achieved by the features listed in the independent claims. Advantageous embodiments and further developments are the subject of the dependent claims.

According to the invention, this object is achieved by means of a rapid standby system. This consists of a generator plant, a turbine-generator plant and / or a Direct methanol fuel cell plant, a consumer plant, a methanol production plant, a deionized and carbon dioxide recovery plant ( CO ₂ ), a tank system for deionized, CO ₂ (liquid) and methanol (MeOH) and a short-term storage. The function of a conventional battery, which has the power storage and power delivery to the content is completely replaced and extended by additional features. The additional functions are, in particular, that the quick-response system described here can provide hydrogen, oxygen, methanol, deionized, carbon dioxide (liquid) and heat in addition to the emergency power and this realized both in undisturbed operation and in a power failure (eg blackout) , Furthermore, the specific costs resulting from investment, maintenance and operating costs, based on a conventional battery storage system, are much lower. The storage capacity of the quick-response system described here can be adapted flexibly according to the consumer requirements.

By means of a short-term storage, which can realize extreme gradients in the current consumption and current output, changing operating modes, transition from the hot-standby mode to rated operation and from rated operation to hot standby mode are easily implemented. Short-term storage, in this case ultracapacitors, is used to support the required mode of operation (situation-specific change of operating mode, here hot standby mode or nominal operation). A hot standby operation is a temporary operation of a plant or multiple plants with minimal power, which are mainly responsible for self-supply. When the grid is disconnected, the methanol production plant of the rapid standby plant switches from nominal operation to hot standby mode, with a methanol reformer of the methanol production plant being switched on, and the turbine generator installation and / or the direct methanol fuel cell installation from hot standby mode to nominal operation. The methanol synthesized by the consumer plant, the methanol production plant of the rapid standby plant is now fed to the turbine generator plant and / or the direct methanol fuel cell plant and thus converted back into chemical energy into electrical energy. Since the time for a load change or the high or shutdown of individual plant components can be very short, short-term storage are used, which guarantee both the freedom of interruption and compliance with applicable quality criteria of the power supply of consumers at the highest level.

The rapid standby plant, which includes a recy-cooling plant, a methanol production plant and a storage facility for methanol, deionized and liquefied CO ₂ containing the methanol production plant ( MEA ) and the regenerative power plant operate alternately in rated operation and in hot standby mode during different phases of operation, converts and stores electrical energy in the form of chemical energy by means of the consumer unit of the rapid standby unit, the methanol production unit, here electrolysis, methanol synthesis, methanol distributor and methanol reformer. The methanol produced is stored in a tank system, here for example a double-layer tank. The chemically stored energy is reconverted in the case of grid separation by means of a direct methanol fuel cell system and / or larger power by means of a turbine-generator plant into electrical energy. The rapid standby facility is equivalent to a stand-alone facility that operates by means of hot-standby operation, which allows for extreme gradients in energy consumption and energy output. Thus, the methanol production plant operates in undisturbed grid operation in normal operation with rated power and the recuperation plant, direct methanol fuel cell system and / or the turbine-generator plant in hot standby mode. In case of failure, z. As a grid separation or a blackout, the recuperation plant, direct methanol fuel cell plant and or the turbine-generator plant operates in nominal operation and the methanol production plant in hot standby mode.

The necessary input media of the rapid readiness system, here in particular deionized for the electrolysis and carbon dioxide for the synthesis of methanol must be recovered with optimal efficiency of the entire system from the exhaust gas of the recuperation plant. The recovery of the input media via a CO ₂ -Wärmepumpenanlage. CO ₂ Heat pump system here means that CO ₂ is used as the refrigerant of the heat pump. The heat of the exhaust gas of the recuperation plant is by means of the evaporator of the CO ₂ Heat pump recovered and fed to the compressed fresh air by means of heat pump condenser. As a result, fuel, here methanol, saved.

The evaporator of the CO ₂ Heat pump absorbed energy is removed from the exhaust gas, whereby the dew point in the exhaust gas is exceeded and condenses water contained in the exhaust gas. The water extracted from the exhaust gas is salt-free and can be used as a deionate for electrolysis. The not inconsiderable heat of condensation is caused by the evaporator CO ₂ Heat pump and connected to the condenser CO ₂ Heat pump forwarded. The anhydrous exhaust gas now consists to a large extent CO ₂ , There CO ₂ is required for the implementation of the methanol synthesis, the exhaust gas via a CO ₂ - Separator with a CO ₂ permeable membrane drove. To the CO ₂ -Abscheidung to make it as optimal as possible, pressure regulators for the exhaust and the CO ₂ at the exit of the CO ₂ Designated. By means of an additional CO ₂ - compressor is the feeder of the recovered CO ₂ in the refrigeration cycle the CO ₂ Heat pump allows. The goal here CO ₂ Liquefaction by means of a CO ₂ Heat pump is necessary because gaseous CO ₂ only very unfavorable and can be stored to a limited extent.

The CO ₂ Heat pump consists of an evaporator, a compressor, a condenser, an expansion valve and two additional units required for the application described here. The additional units concern one CO ₂ (gaseous) feed between evaporator and compressor of CO ₂ Heat pump as well as one CO ₂ - (liquid) -Abführung / supply between the condenser and the expansion valve of the CO ₂ -Wärmepumpe. To the CO ₂ - (liquid) -Abführung / feeding the CO ₂ Heat pump is one CO ₂ - (liquid) tank connected. The CO ₂ - (liquid) tank is connected to the methanol synthesis and supplies them with CO ₂ ,

The quick-response system according to the invention can provide high power almost indefinitely. The storage required here, here deionized tank, CO ₂ (liquid) tank and methanol tank are very cost-effective and superior battery solutions in all respects. In addition, the rapid standby plant via a methanol reformer (methanol to hydrogen and CO ₂ ) which allows the methanol production plant to be operated in hot standby mode.

Since the rapid standby system continuously draws electrical energy from the supply network (generating or transmission network) until the power interruption, the system can also take over additional functions. These include, for example, the traction help for wind farms in connection with a grid rebuilding in island mode, the compensation of voltage drops due to cloud train within a PV park and a gas station function using the self-produced methanol. Furthermore, the system can be used during undisturbed operation for the voltage and frequency maintenance and thus contribute to network stabilization

Advantages over the prior art are above all a fast reaction time to the power supply, a power, heat and methanol production and the recovery and storage of feed media, here deionized and CO ₂ (liquid), to be able to offer great performances even for longer periods. Here, the individual components are known in the prior art, but their combination and supplementation is a novelty.

Another advantage of the present invention is the high efficiency of the entire system, which in particular by the use of a CO ₂ Heat pump is achieved.

Embodiment of the invention

• 1 Schnellbereitschaftsanlage nach Netztrennung. Leistungsschalter zwischen Netz I und Gleichrichter ausgeschaltet.
• 2 CO₂ Verflüssigung mittels CO₂ -Wärmepumpe und Wärmepumpen Druckhaltung
• 3a Doppelschichttank (H₂ O-Tank MeOH-Tank) mit Brandschutzeinrichtung vor der Auslösung, und
• 3b Doppelschichttank (H₂ O-Tank MeOH-Tank) mit Brandschutzeinrichtung nach der Auslösung.

The invention will be explained in more detail with reference to drawings. Show this

• 1 Quick standby system after mains disconnection. Circuit breaker between mains I and rectifier switched off.
• 2 CO ₂ Liquefaction by means of CO ₂ Heat pump and heat pump pressure maintenance
• 3a Double-layer tank ( H ₂ O-tank MeOH tank) with fire protection device before tripping, and
• 3b Double-layer tank ( H ₂ O-tank MeOH tank) with fire protection device after tripping.

The 1 shows a fast-response system SBA for the emergency supply of consumers after a grid failure of grid I, circuit breakers between grid I and inverters SBA switched off. The operation of the rapid-fire system SBA is divided into two operating phases.

In a first phase of operation, the rapid standby facility is ready to go SBA on an undisturbed generation, transmission or distribution network, network I 100 that has a circuit breaker 101 can be switched on or off. In this phase of operation, the rapid-fire system SBA Energie from the upstream power grid, grid I 100 Respectively. The one in a rectifier 102 rectified electricity is supplied by an electrolysis plant 109 added. The electrolysis system 109 produced from water (here deionized), which comes from a water treatment 120 (here deionized production) and / or a water tank 124 , here H ₂ O-tank is provided, hydrogen and oxygen. The hydrogen is shared with CO ₂ that about one CO ₂ capture 118 was won, in one CO ₂ -Wärmepumpe 123 and 123a-h (here heat pump pressure maintenance) was liquefied and in one CO ₂ - (liquid) tank 125 (here CO ₂ Tank), the methanol synthesis 114 fed. In the methanol synthesis 114 methanol is produced and a methanol distributor 119 fed. The methanol distributor 119 leads methanol as needed to a TGA -Brennkammer 117 a turbine-generator plant TGA (consisting of a generator 107 , a turbine 112 , the TGA -Brennkammer 117 . one TGA Heat pumps capacitor 122 , an air compressor 121 ), and / or a direct methanol fuel cell 106 a direct methanol fuel cell plant DMBA (consisting of the direct methanol fuel cell 106 , with a DMBA Heat pumps capacitor 111 and one DMBA -Luftverdichter 116 , a methanol storage 124b and a methanol reformer 115 ). The methanol reformer 115 serves to methanol in CO ₂ and hydrogen to prepare the methanol synthesis 114 during part-load operation (hot-standby operation) does not have to be traveled. The rapid-fire system SBA produces small amounts of electrical energy, heat, deionate and water in this first phase of operation CO ₂ (liquid) via the hot standby operation of the reconversion plant, which is from the direct methanol fuel cell plant DMBA and / or the turbine-generator plant TGA which consists of water, here deionized, and CO2 capture and the deionization and CO2 storage in tank systems, but also large amounts of hydrogen, oxygen, methanol and heat by means of the run in nominal methanol production plant MEA (with an electrolysis 109 , a methanol synthesis 114 , a methanol reformer 115 and a methanol manifold 119 ). The process heat of the methanol synthesis 114 and the oxygen of the electrolysis 109 can be supplied to consumers via a heat supply and / or an air conditioning system with oxygenation. The produced during this phase of operation methanol, deionate and CO ₂ (liquid) are stored and serve the operation in a second phase of operation.

In a second phase of operation is the quick-response system SBA on a disturbed producer, transmission or distribution network, the network I 100 , and is powered by a circuit breaker 101 from the network I 100 , the producer, transmission or distribution network, separately. At the moment of mains separation becomes the turbine generator plant TGA and / or the direct methanol fuel cell plant DMBA transferred from the partial load operation (hot standby operation) in the rated operation and now supplied via the inverter 103 , via the switched-on circuit breaker 104 of the consumer network 105 , the consumer network 105 , Network II. The methanol production plant MEA is transferred from nominal operation to partial load operation (hot standby mode). The turbine generator plant TGA and / or the direct methanol fuel cell plant DMBA be with methanol from a methanol tank 125 operated and deliver DC power in an inverter 103 is converted into three-phase current. The three-phase current supplies the consumers in the consumer network, network II 105 , In addition to direct current supply the turbine generator plant TGA or the direct methanol fuel cell system DMBA also heat. While the heat of the direct methanol fuel cell 106 the direct methanol fuel cell plant DMBA accumulates at a low temperature level and probably can not be used for the supply of consumers, can from the gas turbine 112 emitted heat of the turbine-generator plant TGA , which is obtained at a very high temperature level, used for the heat supply of consumers. The exhaust gas of the direct methanol fuel cell 106 and / or the gas turbine 112 becomes a heat pump evaporator 108 fed and cooled. The resulting condensate, here deionized, is from a water separator 113 taken, filtered (for example by means of activated carbon filter) and a double-layer tank 124 , here the H ₂ O-tank 124a , fed. The CO ₂ -Abscheider 118 removes large quantities of exhaust gas CO ₂ , the refrigerant circuit of a CO ₂ -Wärmepumpe 123 (here heat pump pressure maintenance), which is part of a CO ₂ Liquefaction is to be supplied.

The following are the in 1 circled reference numerals, which represent the connections of the individual plant components with each other, explained in more detail. reference numeral 1 describes the transfer of the primary energy source methanol from the methanol distributor 119 for direct methanol fuel cell 106 and / or to TGA -Brennkammer 117 the gas turbine.

reference numeral 2 describes the transfer of exhaust gas of the direct methanol fuel cell 106 and / or the gas turbine 112 to the evaporator of CO ₂ -Wärmepumpe 108 ,

reference numeral 3 describes the delivery of CO ₂ gaseous at low pressure of the evaporator of CO ₂ -Wärmepumpe 108 to the heat pump pressure maintenance 123 ,

reference numeral 4 describes the delivery of CO ₂ liquid at low pressure of the heat pump pressure maintenance 123 to the evaporator of CO ₂ -Wärmepumpe 108 ,

reference numeral 5 describes the release of deionate from the H ₂ O-tank 124a to the electrolysis 109 ,

reference numeral 6 describes the release of oxygen from the electrolysis 109 to the air compressor 116 the direct methanol fuel cell plant DMBA and / or the air compressor 121 the turbine generator plant TGA ,

reference numeral 7 describes the discharge of anhydrous waste gas from the evaporator CO ₂ Heat pump to the CO ₂ -Abscheider 118 ,

reference numeral 8th describes the delivery of CO ₂ gaseous at high pressure the Heat pumps pressure maintenance 123 to the DMBA Heat pumps capacitor 111 the direct methanol fuel cell plant DMBA and or TGA Heat pumps capacitor 122 the turbine generator plant TGA ,

reference numeral 9 describes the delivery of CO ₂ liquid at high pressure from DMBA Heat pumps capacitor 111 the direct methanol fuel cell plant DMBA and / or the TGA Heat pumps capacitor 122 the turbine generator plant TGA to the pressure maintenance of CO ₂ -Wärmepumpe.

reference numeral 10 describes the heat extraction at the gas turbine 112 the turbine generator plant TGA for the purpose of supplying heat to consumers.

reference numeral 11 describes the transfer of deionized water from the water 113 to the H ₂ O-tank 124a ,

reference numeral 12 describes the transfer of CO ₂ gaseous from the CO ₂ -Tank 125 to the methanol synthesis 114 ,

reference numeral 13 describes the supply of fresh air to the air compressor 116 the direct methanol fuel cell plant DMBA and / or the air compressor 121 the turbine generator plant TGA ,

reference numeral 14 describes the discharge of water and CO ₂ -free exhaust from the CO ₂ -Abscheider 118 ,

reference numeral 15 describes the removal of methanol from the methanol manifold 119 to the methanol reformer 115 ,

reference numeral 16 describes the feeder of CO ₂ gaseous to the refrigerant circuit of the CO ₂ Heat pump at low pressure before the heat pump pressure maintenance 123 ,

reference numeral 17 describes the feeding of methanol from the methanol manifold 119 to the MeOH tank 124b ,

reference numeral 18 describes the removal of methanol from the MeOH tank 124b to the methanol distributor 119 ,

reference numeral 19 describes the supply and delivery of CO ₂ liquid at high pressure to and from CO ₂ Tank to the refrigerant circuit of the CO ₂ Heat pump before the heat pump pressure maintenance 123 ,

2 shows a detailed representation of the heat pump pressure maintenance 123 for the CO ₂ Liquefaction is used. By means of the pressure regulating valve 123a the exhaust pressure is regulated. Together with the pressure control valve 123b , that the CO ₂ Pressure control is used, the required pressure drop over the CO ₂ -Abscheidemembran set. In the event that the pressure for a feed of the recovered CO ₂ in the refrigerant circuit of the heat pump is insufficient, was an additional CO ₂ -Compressor 123c considered. By means of a regulated expansion valve 123e will the CO ₂ - (liquid) -Abführung 123g from and the CO ₂ - (liquid) supply to the refrigerant circuit of the CO ₂ Heat pump regulated. Should the pressure in the refrigerant circuit of the CO ₂ Heat pump above that of the CO ₂ tanks 125 lie, then come one CO ₂ -liquid pump 123h for use. The one used here CO ₂ Heat pump assumes a dual function. On the one hand it takes over the cooling of the exhaust gas and the warming of the fresh air and on the other the CO ₂ -Liquefaction

The 3a and 3b show a double-layer tank with a fire protection device. 3a shows a double-layer tank ( H ₂ O tank - MeOH tank) with the fire protection device before its release, and 3b shows a double-layer tank ( H ₂ O-tank - MeOH tank) with the fire protection device after its release. In the double-layer tank are the H ₂ O-tank 124a and the MeOH tank 124b , The H ₂ O-tank 124a is located above the MeOH tank 124b and will pass through bulkheads opposite the MeOH tank 124b sealed. In the event of a fire, the bulkheads open with a fire alarm tripping unit 124c are connected. After activation of the fire alarm tripping unit water flows out of the H ₂ O-tank 124a in the MeOH tank 124b , By mixing water with methanol, the ignition limit of methanol is reduced so much that the resulting methanol-water mixture can no longer ignite and burn.

The fast-response facility in 1 has a double-layer tank 124 in operation. The filling of the tank system, consisting of the H ₂ O-tank 124a and the MeOH tank 124b , via a methanol synthesis 114 and a methanol manifold 119 , To maintain a continuous production of methanol, a methanol reformer is used 115 , The methanol reformer 115 and an upstream electrolysis unit 109 are able to produce hydrogen in the synthesis of methanol 114 is chemically bound with the addition of carbon dioxide to methanol.

In addition to the production and storage of methanol, the rapid standby facility also has a reverse-current plant, which represents a methanol consumer. An air compressor 116 and or 121 , compress fresh air, too Electrolysis oxygen from the electrolysis 109 can be mixed. In that DMBA Heat pumps capacitor 111 and the TGA -Brennkammer 117 the CO ₂ Heat pump, the fresh air is heat from the exhaust gas of the direct methanol fuel cell 106 and / or the gas turbine 112 fed. The heat of the exhaust gas is removed by means of the evaporator CO ₂ -Wärmepumpe 108 received and by means of the refrigerant circuit of the CO ₂ -Wärmepumpe 108 the DMBA Heat pumps capacitor 111 fed. Here is the refrigerant, eg CO ₂ , after the heat release in the DMBA Heat pumps capacitor 111 and / or im TGA Heat pumps capacitor 122 via an expansion valve 123e relaxed and to the evaporator the CO ₂ -Wärmepumpe 108 forwarded. The heated fresh air becomes one TGA -Brennkammer 117 the gas turbine 112 and / or the direct methanol fuel cell 106 fed and mixed here with methanol, ignited and chemically reacted. The hot exhaust gas drives in the case of the gas turbine 112 one or more turbine wheels of the gas turbine 112 on. The gas turbine 112 is with the generator 107 coupled. Here is the gas turbine 112 generated torque is converted into electrical energy. The electrical energy is available as direct current and can now directly to the consumer via the inverter 103 , the circuit breaker 104 and the consumer network 105 , Network II, are supplied. Should be the consumer in the consumer network 105 , Network II, no need exist, so the generated energy could also be through the rectifier 102 Now operating in inverter mode, the circuit breaker 101 into the supply network 100 , Network I, to be fed back.

The rapid-fire facility has numerous additional facilities for the storage of intermediate products such as water (deionized), CO ₂ (liquid) and serve methanol in a tank system. Best quality water, also known as deionate, passes through the water separator 113 which also contains an activated carbon filter, from the exhaust gas of the gas turbine 112 and / or the direct methanol fuel cell 106 won and the water tank 124a (here H ₂ O-tank).

That is required for methanol synthesis CO ₂ is primarily from the exhaust gas of the gas turbine 112 and / or the direct methanol fuel cell 106 won. This is CO ₂ extracted via a membrane. The gaseous CO ₂ is by means of several pressure regulators and an additional CO ₂ Compressor extracted from the exhaust gas and conditioned so that it is the refrigerant circuit of the CO ₂ Heat pump in front of the refrigerant compressor CO ₂ Heat pump can be supplied. The regulators of the CO ₂ -Druckhaltung 123 , Exhaust pressure regulator with exhaust pressure control valve 123a and CO ₂ Pressure regulator with CO ₂ -Druckregelventil 123b together regulate the necessary pressure gradient for the CO ₂ capture 118 from the exhaust. The CO ₂ -Compressor 123c after CO ₂ capture 118 serves the CO ₂ - pressure increase before CO ₂ Supply to the refrigerant circuit of the CO ₂ Heat pump. The CO ₂ Feeding takes place before CO ₂ Compressor of the CO ₂ -Wärmepumpe. Both CO ₂ -Compressor 123c and 123d are speed-controlled. The liquefied CO ₂ can before the CO ₂ -Expansionsventil over a CO ₂ liquid exhaustion 123g be removed. Should CO ₂ -Coolant in the refrigerant circuit of CO ₂ Heat pump needed, can be liquid CO ₂ from a CO ₂ -Tank 125 over a CO ₂ liquid feed 123f and a CO ₂ liquid pump 123h the refrigerant circuit of the CO ₂ Heat pump to be supplied. The CO ₂ -Tank can also be filled externally.

In the event that the electrolysis 109 The amount of hydrogen provided in hot standby mode is insufficient to complete the methanol synthesis 114 To operate stably, hydrogen and carbon dioxide is used for methanol synthesis 114 parallel switched methanol reformer 115 generated and to the methanol synthesis 114 to hand over.

The methanol refueling system used in the rapid standby plant is a combination of a water tank 124a and a methanol tank 124b Both media can either be in a double-layer tank 124 , Bell tank or bellows tank are stored.

The rapid standby facility for converting and storing electrical energy into chemical energy by means of a methanol production plant MEA is connected to a tank system which contains at least one double-layer tank and / or at least one bell tank and / or at least one bellows tank. That from the exhaust gas of a direct methanol fuel cell 106 and / or a gas turbine 112 recovered water is through a water separator 113 the rapid-fire facility to the water tank 124a (H2O tank) supplied to the tank system. In case of failure (fire), protection systems are activated, which lead to the reduction of the ignitability of the methanol.

LIST OF REFERENCE NUMBERS

MEA

Methanol production plant

TGA

Turbine generator plant

DMBA

Direct methanol fuel cell system

RGA

Recovery plant

TS

tank system

KS

Shortest term memory

1

Methanol feed to direct methanol fuel cell / gas turbine via methanol distributor

2

Exhaust / supply of exhaust gas

3

Discharge / supply of heat pump refrigerant ( CO2 ) in the gas phase

4

Discharge / supply of heat pump refrigerant ( CO2 ) in the liquid phase

5

Removal / Feeding of Deionate

6

Removal of oxygen, e.g. to an air conditioner (not included in the drawing)

7

Discharge / supply of anhydrous exhaust gas

8th

Discharge / supply of CO2 Refrigerant of the heat pump in the gas phase

9

Discharge / supply of CO2 Refrigerant of the heat pump in the liquid phase

10

Heat dissipation to a district heating network (not included in the drawing)

11

Discharge / supply of condensate (deionate)

12

Discharge / supply of CO2

13

Fresh air supply

14

Discharge of water and CO2 -free exhaust

15

Removal / addition of methanol to the methanol reformer

16

Discharge / supply of CO2 gaseous to the refrigeration cycle of CO2 heat pump

17

Removal / supply of methanol from the methanol manifold to the methanol tank

18

Removal / supply of methanol from the methanol tank to the methanol distributor

19

Removal / supply of methanol from the refrigeration circuit of CO2 Heat pump for CO2 tank

100

Grid I (supply network)

101

Circuit breaker (supply network)

102

Power converter (rectifier)

103

Power converter (inverter)

104

Circuit breaker (consumer network)

105

Network II (consumer network)

106

Direct methanol fuel cell

107

Generator (DC generator or alternator with rectifier)

108

Heat Pump evaporators

109

electrolysis

110

Shortest term memory

111

Heat pump condenser for direct methanol fuel cell

112

gas turbine

113

water

114

methanol synthesis

115

methanol reformer

116

Air compressor for air to direct methanol fuel cell

117

Combustion chamber of the gas turbine

118

CO2 separator

119

methanol distributor

120

Demineralized water production

121

Air compressor for air to the combustion chamber of the gas turbine

122

Heat pump condenser for gas turbine

123

Heat pump pressure maintenance

124

H ₂ O tank - MeOH tank (double-layer tank)

125

CO ₂ Tank ( CO ₂ (liquid) tank)

Claims (8)

A method for uninterruptible power supply by means of a rapid standby plant, which includes a reconversion plant, a methanol production plant (MEA) and a storage facility for methanol, deionized and liquefied CO ₂ , wherein the rapid standby plant operates in two operating phases, wherein in a first, trouble-free operating phase, a storage phase In standby mode, the standby regenerative power plant (MEA) and the hot standby standby plant operate in a second phase of operation, a grid failure of a utility grid (100) (grid I), the standby regenerated grid and the methanol production facility (MEA) in hot standby mode work, wherein a methanol reformer (115) of the methanol production plant (MEA) is switched on, so that a consumer network (105) (network II) is supplied without interruption. Method according to Claim 1 characterized in that in the first, trouble-free phase of operation, the rapid-fire facility draws energy from an upstream power grid (100) and rectifies and supplies the power to an electrolysis plant (109), thereafter producing methanol in the methanol-producing plant (MEA) operating at nominal capacity and a methanol manifold ( 119), wherein the methanol distributor (119) methanol to a TGA combustion chamber (117) or a Direct methanol fuel cell (106), a methanol tank (124b) and / or the methanol reformer (115) supplies, and the recuperator operates in hot standby mode, with a small amount of electrical energy, heat, deionized and liquefied CO ₂ incurred which is made available again to the methanol production plant (MEA). Method according to Claim 1 or 2 characterized in that in the first, trouble-free operating phase, a voltage and frequency maintenance is realized by increasing or decreasing the reconversion, which counteracts a power failure. Method according to one of the preceding Claims 1 to 3 characterized in that liquefaction and storage of CO ₂ in a CO ₂ heat pump comprising a DMBA heat pump condenser (111) and / or a TGA heat pump condenser (122), a heat pump evaporator (108), a CO ₂ Separator (118), an exhaust pressure regulator with pressure control valve (123a), a CO ₂ pressure regulator with pressure control valve (123b), an additional CO ₂ compressor (123c), a CO ₂ expansion valve (123e), a CO ₂ liquid discharge from the refrigerant circuit (123g), a CO ₂ liquid supply to the refrigerant circuit (123f) and a CO ₂ liquid pump (123h) is carried out and at the same time recovered heat is supplied to the recuperation plant. Rapid Standby Unit (SBA), which includes a recy-cooling plant, a methanol production plant (MEA) and a storage facility for methanol, deionized and liquefied CO ₂ , with the methanol production facility (MEA) and the recy-grid plant operating alternately in nominal and hot-standby modes at different operating phases wherein the rapid transit system (SBA) is connected to a utility grid, generation, transmission or distribution network (100), grid I, via a circuit breaker (104) and a consumer grid (105), grid II, via a DC link, wherein the DC link with energy storage, the methanol production plant (MEA) and a short-term storage (110) is in operative connection, the rapid standby plant (SBA) a direct current plant in the form of a direct methanol fuel cell plant (DMBA) and / or a turbine-generator plant (TGA) and a methanol storage, MeOH tank (124b) around in which the methanol reservoirs (124b) are in turn connected to the turbine-generator plant (TGA) or the direct methanol fuel cell plant (DMBA), surplus electricity from the grid network I (100) and / or the direct methanol fuel cell plant (DMBA) and / or the Turbine Generator Plant (TGA) is stored in methanol storage in the form of methanol in a methanol tank (124b) (MeOH tank) and is available for reconversion in an emergency. Fast-response plant after Claim 5 , characterized in that the direct methanol fuel cell system (DMBA) and / or the turbine-generator plant (TGA) via a heat pump and a water tank (124a) and a CO ₂ tank (125) is connected to the methanol storage, wherein exhaust gas from the direct methanol fuel cell (106) and / or the turbine-generator plant (TGA) for the recovery of water (deionized) and CO ₂ is used. Fast-response plant after Claim 6 , characterized in that the water tank (124a) with the methanol tank (124b) forms a unit. Fast-response plant after Claim 6 , characterized in that the CO ₂ liquefaction a CO ₂ separator (118), an exhaust pressure regulator with pressure control valve (123 a), a CO ₂ compressor (411 c) after CO ₂ separator (123 c), a CO ₂ - Compressor of the CO ₂ heat pump (123d), a CO ₂ expansion valve (123e) of the heat pump, a CO ₂ liquid supply (123f) in the refrigerant circuit, a CO ₂ liquid discharge (123g) from the refrigerant circuit, a CO ₂ liquid pump (123h), a CO ₂ tank (125), a heat pump evaporator (108) and a DMBA heat pump condenser (111) and / or a TGA heat pump condenser (122), wherein the heat pump CO ₂ compressor (123d) and the heat pump CO ₂ expansion valve (123e) between the evaporator (108) and the DMBA heat pump condenser (111) and / or the TGA heat pump condenser (122) a CO ₂ -Kältemittelkreislauf is arranged, wherein the CO ₂ separator (118) in front of the CO ₂ compressor (123 d) gaseous it feeds CO ₂ into the refrigerant circuit and liquid CO ₂ after the DMBA heat pump condenser (111) and / or the TGA heat pump condenser (122) from the refrigerant circuit in the CO ₂ tank (125) is discharged.

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